BRPI0502045B1 - process for preparing one or more catalyst ignition promoters - Google Patents

Abstract

"CATALYST IGNITION PROMOTER ARTICLE, PROCESSES FOR THE PREPARATION OF ONE OR MORE CATALYST IGNITION PROMOTER ARTICLES, TO REDUCE THE METHANE AND AMMONIA IGNITION TEMPERATURE IN THE MANUFACTURE OF HYDROGEN CYANIDE, AND, FOR IGNITION OF ONE OR MORE CATALYST. The inventors have found catalyst ignition promoters comprising one or more activated metals. Catalyst ignition promoters are easily prepared from numerous metal sources, including spent catalysts, are activated quickly and provide effective ignition of the catalyst regardless of the quality of the metals comprising the catalytic converter. The one or more activated metals that comprise the ignition promoter are prepared by placing them in contact with one or more chemical treatments. The activated metal components are prepared in the form of appropriate articles, referred to as ignition strips, which are placed in contact with one or more oxidizing coupling catalysts, typically in the form of screens. Ignition promoters reduce the activation energy for ignition of the catalyst (also referred to as ignition), allowing the ignition of new, used, contaminated, damaged catalyst screens and combinations thereof, at relatively low auto-ignition temperatures .

Description

The present invention is related to the promotion of ignition of catalysts used in reactions catalyzed by metals. In particular, the invention is directed to articles that promote ignition used in metal-catalyzed oxidation reactions on an industrial scale including, but not limited to, manufacture of hydrogen cyanide (Andrussov process), nitric acid (Ostwald process), synthesis gas (carbon monoxide and hydrogen), olefins, alkynes and formaldehyde. The articles of the invention that promote ignition improve the ignition efficiency of the catalytic converter, provide lower temperatures for the ignition of the catalyst, provide the ignition of used, damaged or contaminated catalysts, avoid multiple ignition failures and increase the production of products with a constant conversion of the reactant (s) of a particular catalyst. The invention is further directed to methods for preparing activated metal ignition promoters and to processes catalyzed by metal using catalyst ignition promoters.

Numerous important chemical manufacturing processes are oxidations catalyzed by metals. Examples include, but are not limited to, manufacturing hydrogen cyanide from methane and ammonia, acetylene from methane and oxygen, nitric acid from ammonia oxidation (Ostwald process), synthesis gas from reform by methane steam, ethylene from ethane, propylene from propane, and formaldehyde from methanol. The commercial manufacture of hydrogen cyanide is an oxidizing coupling reaction catalyzed by methane and ammonia metal. Reagent ignition occurs by passing preheated feed gases over platinum / rhodium screens at temperatures above 270 ° C. Unfortunately, ignition problems at startup, including failures to ignite new catalysts, used catalysts, contaminated catalysts and Damaged catalysts result in significant production losses, including additional catalyst costs and reactor downtime associated with subsequent failed attempts to ignite the catalyst in a fresh start. In addition, the production as a whole of the catalyzed products is negatively affected as a result of one or more catalyst ignition failures. There are numerous possible causes for catalyst ignition failures including, but not limited to, contamination of the catalyst due to one or more organic waste from the feed gases, one or more lubricating and / or compressor oils associated with the reactor, and combinations the same. Despite the techniques known in this technology to improve the catalyzed processes with ignition, including the flammability of the incoming feed reactant (s), the rise in the feed temperature and the increase in pressure in the reactor, the problems in ignition of the catalyst have provided numerous obstacles to be overcome.

Ignition of the catalyst (also referred to as igniting the catalyst) at a relatively low temperature is highly desirable. US Patent No. 4863893 describes a way to decrease the ignition temperature for oxidation of ammonia in the manufacture of nitric acid, which involves the use of platinum-rhodium and platinum-palladium-rhodium screens that carry a platinum coating. in excess of 4.0 g / m2 of platinum charge in relation to the mass of the screen area (considered as a slab) to decrease the ignition temperature required for ignition in the oxidation of ammonia, especially if hydrogen is used as ignition fuel. Unfortunately, the coating of large areas, or of the total area, of the catalyst woven fabrics with platinum black is expensive, complicated and not commercially feasible. Therefore, it should be highly desirable that one or more catalyst ignition promoters are provided that can initiate ignition of the catalyst at relatively low auto-ignition temperatures. An impediment to an economically viable ignition promotion process for catalysts is the identification of one or more optimal ignition promoters that will provide adequate ignition of the catalyst, including ignition of the catalyst in the presence of one or more contaminants, the ignition of used catalysts, the ignition of damaged catalysts, the ignition of the catalyst coupled with a good conversion of the product (s) in a constant conversion of the reagent (s), including also an appropriate selectivity for the product. Despite attempts to provide new and better catalysts for oxidations catalyzed by metals, no attempt has been made to identify catalyst ignition promoters or for those using activated metals as ignition strips for igniting the catalyst.

The inventors have found catalyst ignition promoters that comprise one or more activated metals and that are easily prepared from numerous metal sources, including used catalysts, new catalysts, damaged catalysts, contaminated catalysts and combinations thereof. The metals are activated quickly and are prepared in the form of ignition promoting articles that are placed in contact with the catalysts to provide effective ignition of the catalyst, regardless of the quality of the metals that comprise the catalytic converter. The one or more activated metals that comprise the ignition promoter are prepared by placing them in contact with one or more chemical treatments, or combinations of one or more chemical and physical treatments. The activated metal components are manufactured in the form of appropriate ignition promoting articles, referred to as ignition strips, which are brought into contact with one or more catalysts. The ignition promoters reduce the activation energy for the ignition of the catalyst (also referred to as ignition), allowing the ignition of catalyst screens that are new, used, contaminated, damaged, or combinations thereof, at auto-ignition temperatures. relatively low.

Consequently, an article promoting catalytic ignition is provided which comprises: one or more metals selected from the group consisting of nickel, platinum, palladium, cobalt, rhodium, silver, gold, copper, iridium, rhenium, cerium, alloys thereof , binary alloys thereof, ternary alloys thereof, intermetallic alloys thereof and combinations thereof, the article comprising still less than 1 percent by weight of a metal coating, based on the weight of the article, of one or more selected metals the group consisting of nickel, platinum, palladium, cobalt, rhodium, silver, gold, copper, iridium, rhenium, cerium, alloys thereof, binary alloys thereof, ternary alloys thereof, intermetallic alloys thereof and combinations thereof; where the metal is deposited on the article using one or more chemical treatments or a combination of one or more chemical and physical treatments.

A process for preparing one or more catalyst ignition promoters is provided comprising the step of treating one or more sections of a catalyst comprising one or more metals selected from the group consisting of nickel, platinum, palladium, cobalt, rhodium, silver , gold, copper, iridium, rhenium, cerium, alloys thereof, binary alloys thereof, ternary alloys thereof, intermetallics thereof and combinations thereof with one or more chemical treatments or a combination of one or more chemical and physical treatments ; where each section of the catalyst is coated with a metal coating comprising less than 1 percent by weight of a metal coating, based on the weight of the catalyst, of one or more metals selected from the group consisting of nickel, platinum, palladium , cobalt, rhodium, silver, gold, copper, iridium, rhenium, cene, alloys thereof, binary alloys thereof, ternary alloys thereof, intermetallic alloys thereof and combinations thereof.

A process for preparing one or more articles promoting catalyst ignition is provided comprising the steps of: (a) preparing one or more articles from one or more sections of a catalyst comprising one or more metals selected from the group consisting of nickel, platinum, palladium, cobalt, rhodium, silver, gold, copper, iridium, rhenium, cerium, alloys thereof, binary alloys thereof, ternary alloys thereof, intermetallic alloys thereof and combinations thereof; (b) contacting each article with one or more chemical treatments or a combination of one or more chemical and physical treatments, where each article is coated with a metal coating that comprises less than 1 weight percent of a metal coating , based on the weight of the article, of one or more metals selected from the group consisting of nickel, platinum, palladium, cobalt, rhodium, silver, gold, copper, iridium, rhenium, cerium, alloys thereof, binary alloys thereof, ternary alloys thereof, intermetallic alloys and combinations thereof.

A process for decreasing the ignition temperature of one or more reagents using one or more metal catalysts is provided, which comprises the step of bringing each catalyst into contact with one or more ignition promoting articles.

A process is provided to promote the ignition of one or more catalysts selected from the group consisting of new catalysts, used catalysts, recycled catalysts, reconditioned catalysts, damaged catalysts, contaminated catalysts and combinations thereof, comprising the step of contacting each catalyst with one or more ignition-promoting articles.

A process is provided for the reconstruction of catalytic sites in a catalyst, comprising the step of contacting the catalyst with one or more ignition-promoting articles, or treating one or more sections of a catalyst comprising one or more metals selected from the group consisting of nickel, platinum, palladium, cobalt, rhodium, silver, gold, copper, iridium, rhenium, cerium, alloys thereof, binary alloys thereof, ternary alloys thereof, intermetallic alloys thereof and combinations thereof with one or more chemical treatments or a combination of one or more chemical and physical treatments; where each section of the catalyst is coated with a metal coating comprising less than 1 percent by weight of a metal coating, based on the weight of the catalyst, of one or more metals selected from the group consisting of nickel, platinum, palladium , cobalt, rhodium, silver, gold, copper, iridium, rhenium, cerium, alloys thereof, binary alloys thereof, ternary alloys thereof, intermetallic alloys thereof and combinations thereof.

A process is provided for increasing the catalytic sites in a catalyst comprising the step of contacting the catalyst with one or more ignition promoting articles or treating one or more sections of a catalyst comprising one or more metals selected from the group consisting of nickel , platinum, palladium, cobalt, rhodium, silver, gold, copper, iridium, rhenium, cerium, alloys thereof, binary alloys thereof, ternary alloys thereof, intermetallic metals thereof and combinations thereof with one or more chemical treatments or a combination of one or more chemical and physical treatments; where each section of the catalyst is coated with a metal coating comprising less than 1 percent by weight of a metal coating, based on the weight of the catalyst, of one or more metals selected from the group consisting of nickel, platinum, palladium , cobalt, rhodium, silver, gold, copper, iridium, rhenium, cerium, alloys of the same, binary alloys of the same, ternary alloys of the same, intermetallic of the same and combinations thereof.

A process for the manufacture of hydrogen cyanide is provided which comprises the step of contacting a platinum / rhodium catalyst with one or more ignition-promoting articles.

Accordingly, the present invention provides one or more articles for promoting ignition in catalysts for metal catalyzed reactions on an industrial scale. Ignition promotion articles in catalysts are easily prepared from numerous metal sources, including but not limited to, for example, metals used in the preparation of catalysts, new catalysts, used catalysts, damaged catalysts, recycled catalysts, reconditioned catalysts, contaminated catalysts and combinations thereof. According to an embodiment, a specific ignition-promoting article is prepared from its corresponding catalyst as the metal source. According to a separate embodiment, the specific ignition-promoting article is prepared from metal sources other than the corresponding catalyst. Ignition promoters reduce the activation energy for ignition of the catalyst (also referred to as ignition), allowing the ignition of catalyst screens that are new, used, contaminated, damaged, recycled, reconditioned or combinations thereof, at auto temperatures. relatively low ignition.

Suitable metals and metal sources used in accordance with the invention include, but are not limited to, nickel, platinum, palladium, cobalt, rhodium, silver, gold, copper, iridium, rhenium, ruthenium, molybdenum, vanadium, niobium, Indian, cerium and their alloys. Suitable alloys include, but are not limited to, for example, binary alloys such as Pt / Rh, Pt / Ni, Pt / Co, Pt / Ag, Pt / Au, Pt / Cu, Pt / Ir, Pt / Re, Pt / Ru, Pt / Mo, Pt / Ce, Pd / Rh, Pd / Ni, Pd / Co, Pd / Ag, Pd / Cu, Rh / Co, Rh / Ni, Rh / Ag and Rh / Ru; ternary alloys such as Pt / Pd / Rh, Pt / Pd / Ni, Pt / Pd / Ag, Pt / Pd / Ru and Pt / Pd / Co. Other suitable metals include intermetals selected from the group consisting of nickel, platinum, palladium, cobalt, rhodium, silver, gold, copper, iridium, rhenium, ruthenium, molybdenum and cerium. Examples include, but are not limited to, Pto.i- i, 99P ^ ri-0.99-0.011 PtsRh, Nioj-i ^ Pto ^ -o.oi, PtxRhy, PtxNiy, PtxCOy, PtxRhyIr2 and PtxRhyIrz, where x = 0.1-100, y = 0.1-100 and z = 0.1-100. As used here, intermetallic refers to compounds, distinct intermediates having stoichiometric or non-stoichiometric formulas, when compared to alloys (solid solutions of two or more metals).

The ignition promoter article is prepared in a variety of three-dimensional forms. According to one embodiment, the three-dimensional shape of a specific ignition-promoting article corresponds to the three-dimensional shape of a specific catalyst. According to a separate embodiment, the three-dimensional shape of a specific ignition-promoting article corresponds to a three-dimensional shape different from that of a specific catalyst. Suitable forms of the ignition-promoting article include, but are not limited to, for example, fibers, wires, needles, foams, spongy masses, porous solids, porous particles, fibrous plates, mesh screens, woven fabrics and combinations thereof. According to one embodiment, the ignition-promoting articles take the form of the catalyst used in a specific metal-catalyzed reaction. According to a separate embodiment, the ignition-promoting articles take a different shape (a catalyst used in a specific metal-catalyzed reaction.

The ignition-promoting article also comprises less than 1 weight percent of a metal coating, based on the weight of the article. According to one embodiment, the weight of the metal coating, based on the weight of the article, is between 0.01 and 1 weight percent, including from 0.05 to 0.75 weight percent. The metal coating comprises one or more metals selected from the group consisting of nickel, platinum, palladium, cobalt, rhodium, silver, gold, copper, iridium, rhenium, ruthenium, molybdenum, vanadium, niobium, indium, cerium, the alloys of the same, the binary alloys thereof, the ternary alloys thereof, the intermetallic alloys thereof and combinations thereof; where the metal is deposited on the article using one or more chemical treatments or a combination of one or more chemical and physical treatments. According to one embodiment, the metal coating comprises the same composition as that of the catalyst. According to a separate embodiment, the metal coating comprises a different composition than that of the catalyst.

The amount of the metal charge in the ignition promoter article is less than 0.5 g / m2 of metal (s) per square meter of the ignition promoter article. According to one embodiment the amount of the metal filler is between 0.0003 g / cm2 at Q, 5 g / m2, including from 0.004 g / cm2 to 0.001 g / m2.

The process for preparing one or more articles promoting catalyst ignition comprises the steps of: (a) preparing one or more articles of one or more sections of a catalyst comprising one or more metals selected from the group consisting of nickel, platinum , palladium, cobalt, rhodium, silver, gold, copper, iridium, rhenium, cerium, alloys thereof, binary alloys I, ternary alloys thereof, intermetallic alloys and combinations thereof; (b) contacting each article with one or more chemical treatments or a combination of one or more chemical and physical treatments, where each article is coated with a metal coating that comprises less than 1 weight percent of a metal coating , based on the weight of the article, of one or more metals selected from the group consisting of nickel, platinum ^ palladium, cobalt, rhodium, silver, gold, copper, iridium, rhenium, cerium, alloys thereof, binary alloys thereof, ternary alloys thereof, intermetallic alloys and combinations thereof.

The activated metal is deposited on the ignition promoter article or on sections of the catalyst using one or more chemical treatments or a combination of one or more chemical and physical treatments. As used herein, activated metals refer to metals that have a greater amount and proportion of catalytically active sites compared to untreated metals. According to an embodiment of the invention, the activated metal components are prepared in the form of ignition-promoting articles, also referred to as ignition strips, and which are brought into contact with a specific catalyst. According to a separate embodiment, the activated metal components are incorporated into the treated sections of the catalyst. An advantage of the invention is that ignition promoters in the form of small strips or treated sections of the catalyst have a large total surface area, compared to 15 fully coated catalytic screens, characterized by excess surface coatings of 50 cm2 / g 500 cm2 / g of metal required for ignition. A second advantage is that the metal charge on the ignition promoters of the present invention is small compared to conventional methods that require at least 0.5 g of metal / m2 of> 0 catalyst for ignition. A third advantage of the invention is that the catalyst ignition articles are quickly prepared and placed in contact with the catalyst, minimizing the reactor downtime, when compared to the special operations required for the coating of large areas of the catalysts, storage the 25 coated catalysts and the corresponding costs that are associated with the relatively large amounts of platinum required for the coating. A fourth advantage of the invention is that used catalysts, damaged catalysts, contaminated catalysts and combinations thereof are successfully ignored using the ignition-promoting articles.

One or more chemical treatments or combinations of one or more chemical and physical treatments are used to incorporate activated metals in the ignition promoters, in such a way that they will contain larger quantities and proportions of catalytically active sites, compared to non-metals. treated. Chemical treatments and appropriate physical treatments include, but are not limited to, for example, contacting the ignition promoter strip with one or more metal compounds. The one or more metal compounds are thermally and photochemically decomposed, including chemically and electrochemically reduced, to provide active sites of the catalytic metal in the ignition-promoting strips. Other methods for incorporating activated metals into the ignition-promoting strips include, but are not limited to, for example, chemical vapor deposition of the catalytically active metals on the surface of the ignition strip, precipitation of catalytically active metals on the surface of the ignition strip using deposition without electricity, or catalytically electrodepositing active metals on the ignition strip surface, projecting catalytically active metals on the ignition strip surface, and physical vapor deposition of catalytically active metals on the ignition strip surface.

Suitable metal compounds used for the deposition of activated metals in the ignition-promoting strips include, but are not limited to, for example, contacting the ignition-promoting article with metal compounds selected from the group consisting of platinum black, Ni Raney, metal halides where metals include, but are not limited to, for example, nickel, platinum, palladium, cobalt, rhodium, silver, gold, copper, iridium, rhenium, ruthenium, molybdenum, Vanadium, niobium, indium, cerium and combinations thereof, and where halides are selected from the group consisting of F, Cl, Br, I and combinations thereof, complexes of warm metal, organometallic compounds, including but not limited to, for example, carbonyls of metal and metal olefins where metal includes, but is not limited to, for example, nickel, platinum, palladium, cobalt, rhodium, silver, gold, copper, iridium, rhenium, ruthenium, molybdenum, vanadium, niobium, indium, cerium and combinations thereof, and h complexes metal idict.

A process is provided for igniting one or more catalysts, selected from the group consisting of new catalysts, used catalysts, recycled catalysts, reconditioned catalysts, damaged catalysts, contaminated catalysts and combinations thereof, and which comprises the step of contacting each catalyst with one or more ignition-promoting articles.

According to one embodiment, the ignition-promoting articles of the invention reduce the activation energy for igniting (igniting) a new catalyst, allowing the new catalyst to ignite at relatively lower temperatures, namely, similar temperatures those of corresponding used catalysts that have relatively higher surface areas. The ignition of the reactants occurs in the places where the ignition promoting articles are in contact with the catalyst, leading then to a complete ignition of the catalyst, as confirmed by visual observations and by means of temperature measurements using thermocouple devices.

According to a separate embodiment, the ignition-promoting articles of the invention provide for the ignition of catalysts contaminated with one or more organic compounds which include, but are not limited to, for example, lubricating oils, compressor oils, paraffins, C8-C22 hydrocarbons in reagents, oil residues, residues in reagents, reactor discharges, soot, dust, product residues and combinations thereof. The ignition of the reagents takes place in uncontaminated places where the ignition promoting articles come in contact with the catalyst, leading then to a complete ignition of the catalyst, as confirmed by visual observations and temperature measurements using thermocouple devices. The promoted ignition is successful in contaminated catalysts using a short preheating period while the feed is admitted to the catalytic converter for immediate ignition1 An advantage is that this method minimizes additional contamination of the catalysts, compared to conventional ignition methods.

According to a separate embodiment, the ignition promoting articles of the invention provide for the ignition of catalysts damaged by events that include, but are not limited to, for example, high temperature with burning of the reagents, oxidation of the catalyst, destruction of catalyst sites, unfavorable reactions that do not lead to the products and their combinations. Ignition-promoting articles are used in contact with damaged catalyst sites, providing an additional advantage for repairing the damaged catalyst site. The ignition of the reactants occurs in the damaged places where the ignition promoting articles are in contact with the catalyst, leading then to a complete ignition of the catalyst, as confirmed by visual observations and temperature measurements using devices with thermocouples.

According to a separate embodiment, the ignition promoting articles of the invention provide for the ignition of spent catalysts, recycled catalysts and reconditioned catalysts through the reconstruction of catalytic sites. The generation of specific catalytic sites for the product is a dynamic process during catalysis and the catalytic sites are continuously created and destroyed. In some cases, the destruction of the catalytic sites is so severe that the production of the product falls precipitously and the reaction is stopped. Ignition promoting articles are used successfully to rebuild catalytic sites with immediate ignition of used, recycled or refurbished catalysts. The ignition of the reagents occurs in the reconstructed catalytic sites I where the ignition-promoting articles are in contact with the catalyst, leading then to a complete ignition of the catalyst, as confirmed by visual observations and temperature measurements using devices with thermocouples.

The present invention provides one or more ignition promoting articles for metal catalyzed reactions on an industrial scale.

According to one embodiment, the invention provides activated ignition-promoting articles for the production of hydrogen cyanide from an oxidizing coupling of methane and ammonia using Pt / Rh screens. Such screens typically consist of metal alloys, including but not limited to, for example, Pt / Rh (90% / 10%), Pt / Rh (95% / 5%) and Pt / Rh / Pd (90% / 5 % / 5%). The screens are typically sieves woven from metal wires that have a minimum diameter of about 0.008 cm with at least 31.5 openings per centimeter. Ignition-promoting articles are prepared by cutting irregular or regular sections with dimensions 7-10 of a used catalyst screen having a minimum area of 4 cm. The screens were placed in an aqueous solution of a platinum compound and were calcined to decompose the platinum compound and coat the metal on each screen with Pt. The metal charge in each article ranged from 0.01 to 1% by weight of Pt, based on the weight of the article. The articles were placed in contact with a Pt / Rh catalyst and the ignition temperatures were measured by devices with thermocouples. The ignition of the preheated feed gases occurred in the vicinity of the ignition promoting articles, at temperatures between 230 and 260 ° C and which rose to operating temperatures between 1100 and 1250 ° C in a plant operating in an optimized reagent mass production . The ignition on the first attempt occurred with a frequency above 95%. The catalytic activation of hydrogen cyanide occurs at crystalline cyanide sites on the surface of the multilayer screen.

Suitable compounds used to chemically treat and incorporate activated metals in the ignition priming strips include, but are not limited to, for example, compounds selected from the group consisting of: platinum black, platinum sponge, Raney Ni, platinum halides (III) (PtF2, PtCl2, PtBr2 and Ptl2, platinum (IV) halides (PtF4, PtCl4, PtBr4 and Ptl4), platinum (VI) halides (PtF62 ', PtCl62', PtBr62 'and PtV'), Zeise salts, Pt (II), Pt (IV) and Pt (VI) ammonia complexes, chloroplatinic acid (H2PtCl6), bromoplatinic acid (H2PtBr6), Pt (O) organometallic compounds including but not limited to, for example, compounds bis (ethylene) platinum and divinylteralkylsiloxanePt (O) and platinum acetylacetonate compounds, platinum cyanide and platinum hydride complexes. A catalytic form of platinum, platinum black, is deposited on the ignition strips by thermal, photochemical decomposition of the platinum compounds listed above The electrochemical and chemical reduction of compounds platinum also generates platinum black in the ignition strips. Platinum, as well as other catalytic metals (e.g., Ni Raney), is also deposited on the ignition strips by chemical treatments or combinations of chemical and physical treatments.

The generation of specific hydrogen cyanide catalytic sites is a dynamic process, with the catalytic sites being continuously created and destroyed as the reaction proceeds. During the catalytic process, the surface area of the catalytic mesh increases considerably, restructuring itself to form facets, depressions, hairs and crystalline catalytic sites and amorphous regions that are catalytically inactive. The restructuring of the catalytic sites on the screen is anisotropic in nature and the catalytically active crystalline sites migrate to the catalytically inactive amorphous sites. Near the end of the screen's useful life, the reaction sites reach the lower layers of metal and the aged screen stops the generation of new catalytic cyanide sites. In addition, the population of catalytic sites is gradually reduced over the life of the catalyst, which results in reduced production of hydrogen cyanide, when the catalytic screen is then replaced.

The ignition promoters reduce the activation energy for the ignition of the catalyst (also referred to as ignition), allowing the ignition of catalyst screens that are new, used, contaminated, damaged and the combinations thereof, at auto-ignition temperatures. relatively low. The catalytic ignition promoters of the invention restore the catalytic sites of hydrogen cyanide to active crystalline forms. Ignition promoters furthermore enhance the activity of a spent catalyst, resulting in a net increase in the catalytic cyanide sites. The use of ignition promoters for activated catalysts resulted in an unexpected improvement in the reliability of ignition in the manufacture of hydrogen cyanide from methane and ammonia, resulting in higher production, a reduction in the burning of ammonia and methane, which damages and / or destroys the catalyst, and in an increased service life for the catalyst. 1

According to a separate embodiment, the invention provides activated ignition-promoting articles for the metal-catalyzed production of nitric acid from the oxidation of an ammonia-air mixture. The fabrics typically used for the production of nitric acid typically consist of metal alloys of the platinum group, in principle 90% Pt: 10% Rh and 90% Pt: 5% Rh: 5% Pd, and are typically fabrics woven with about 0.008 cm in diameter and about 31.5 openings per linear centimeter. Other combinations of opening and wire diameter can be used to advantage. For a detailed report see Roberts and Gillespie, “Estimation of Platinum Catalyst Requirement for Ammonia Oxidation”, 45 Advances in Chemistry Series No. 133, Chemical Reaction Engineering II, pages 600-611. See also US Patent No. 3660024. Ignition-promoting articles are prepared by cutting 7-10 sections with irregular or regular dimensions, from a used catalyst screen, having a minimum area of 4 cm. The screens were placed in an aqueous solution of a platinum compound and then calcined to decompose the platinum compound to form a Pt metal coating on each screen. The metal charge in each article ranged from 0.01 to 1% by weight of Pt, based on the weight of the article. The articles were placed in contact with the Pt / Rh catalyst and the ignition temperatures were measured by devices with thermocouples. The ignition of the preheated feed gases occurred in the vicinity of the articles promoting ignition at temperatures between 230 and 260 ° C, in a plant operating at a production mass of 41494.6 kg / m2-h (8500 lbs / ft2) -H). The ignition on the first attempt occurred with a frequency above 90%.

The activated ignition promoting articles are prepared from screen sections as described above and treated with chloroplatinic acid and then by a thermal reduction to generate a high concentration of platinum black sites in the ignition strips, compared to the catalytic screen. The ignition-promoting articles of the invention have numerous advantages over completely coating conventional ammonia oxidation catalyst screens. An advantage is that the metal charge in the ignition promoters of the present invention is less than 0.5 g of metal / m2 of catalyst screen required for ignition. A second advantage of the invention is that the catalyst ignition articles are quickly prepared and placed in contact with the catalyst, minimizing the reactor downtime; compared to the special operations required to coat large areas of catalyst, for the safe storage of coated catalysts and the cost associated with the required platinum coating. A third advantage of the invention is that the used catalysts, the damaged catalysts, the contaminated catalysts and combinations thereof are successfully ignored using the ignition promoting articles.

According to a separate embodiment, the invention provides activated ignition promoting articles for the production catalyzed by acetylene metal, from the oxidation of a methane-air mixture. Conventional ignition of the reagents occurs by passing the preheated feed gases into multiple layers of platinum mesh and Pt coated monoliths (eg, a-alumina), or rhodium mesh, at temperatures above 500 to 800 ° C. The catalytic activation of methane and the subsequent coupling of methyl radicals occurs in crystalline locations on the surface of the catalyst. The activated ignition strips of the invention are prepared from articles produced from catalysts by depositing a coating of Pt black from the platinum compounds described above, PtzC, combinations of Pt black and Pt / C or by depositing a coating of Pt Rh metal thermally decomposing rhodium halides (eg, RhCl3, (NH3) 2RhCl6). Ignition-promoting articles are prepared by cutting 7-10 sections with irregular or regular dimensions, from a used catalyst screen, having a minimum area of 4 cm2. The metal load in each article ranged from 0.01 to 1% by weight of Pt or Rh, based on the weight of the article. The articles were placed in contact with the catalyst and the ignition temperatures were measured by devices with thermocouples. The ignition of the preheated feed gases occurred in the vicinity of the articles promoting ignition at temperatures below 500 ° C and operating at spatial speeds of at least 105 h "1.

According to a separate embodiment, the invention provides activated ignition-promoting articles for the metal catalyzed production of C2-C8 alkenes, from the oxidation of a C2-C8-air alkanes mixture. Reagent ignition occurs by passing preheated feed gases in multiple layers of supported and unsupported platinum or rhodium catalysts at temperatures above 500 ° C. The activated ignition strips of the invention are prepared from articles produced from catalysts by depositing a coating of Pt black from the platinum compounds described above, Pt / C, combinations of Pt black and Pt / C or by depositing a Rh metal coating thermally decomposing rhodium halides (eg,! RhCl3 , (NH3) 2RhCl6). Ignition-promoting articles are prepared by cutting 7-10 sections with irregular or regular dimensions, from a used catalyst screen, having a minimum area of 4 cm2. The metal load in each article ranged from 0.01 to 1% by weight of Pt or Rh, based on the weight of the article. The articles were placed in contact with the catalyst and the ignition temperatures were measured by devices with thermocouples. The ignition of the preheated feed gases occurred in the vicinity of the articles promoting ignition at temperatures below 500 ° C and operating at spatial speeds of at least 105 h "'.

According to a separate embodiment, the invention provides activated ignition-promoting articles for the catalyzed production of synthesis gas metal from the oxidation of methane by steam reforming. Reagents ignite by passing preheated feed gases over a Ni catalyst (including Ni supported on a ceramic monolith) at temperatures between 1000-1500 ° C, under pressure (2000 kPa to 8500 kPa). The activated ignition strips of the invention are prepared from articles produced from catalysts by depositing a Ni coating of nickel compounds, including but not limited to, for example, Ni Raney from an alloy, AlNi as described above, or by depositing a coating Ni metal by chemically reducing or thermally decomposing nickel halides (eg, NIC12), nickel carbonyl Ni (CO) 4 or organometallic Ni compounds. Ignition-promoting articles are prepared by cutting 7-10 sections with irregular or regular dimensions, from a used catalyst screen, having a minimum area of 4 cm2. The metal charge in each article ranged from 0.01 to 1% by weight of Ni, based on the weight of the article. The articles were placed in contact with the catalyst and the ignition temperatures were measured by devices with thermocouples. The ignition of the preheated feed gases occurred in the vicinity of the articles promoting ignition at temperatures below 1000 ° C and operating at spatial speeds of at least 104 h '.

According to a separate embodiment, the invention provides activated ignition promoting articles for formaldehyde metal catalyzed production from methanol oxidation using a silver catalyst and wet gas recycle (WGR) or a Pt coated monolith with short contact times. Reagents ignite by passing preheated feed gases over crystalline silver needles at temperatures above 600 ° C, under pressure. Catalytic activation of methane occurs at crystalline H2CO sites on the surface of the multilayer screen. The activated ignition strips of the invention are prepared from articles produced from the Ag catalyst by depositing an Ag coating of silver compounds, including but not limited to, for example, silver halides (eg, AgCl, AgCl2), carbonyl silver Ag (CO) or Ag organometallic compounds. Ignition promoting articles are prepared by cutting 7-10 sections with irregular or regular dimensions, from a used catalyst screen, having a minimum area of 4 cm2. The metal charge in each article ranged from 0.01 to 1% by weight of Ag, based on the weight of the article. The articles were placed in contact with the catalyst and the ignition temperatures were measured by devices with thermocouples. The ignition of the preheated feed gases occurred in the vicinity of the articles promoting ignition at temperatures below 600 ° C and operating at spatial speeds of at least 104 h * 1.

The following illustrative examples are provided to further demonstrate the usefulness of the present invention and are in no way considered to be limiting. Furthermore, the examples provided are representative examples that broadly consider the claimed scope of the invention. EXAMPLE Strips of pieces of worn or worn platinum canvas were each cut as irregular sections (2.54 cm by 5.08 cm). The strips were activated by immersing them in an aqueous solution of chloroplatinic acid (13.7% containing 6.5% Pt) for 2 hours at room temperature, in a crucible. The chloroplatinic acid solution was decanted and the crucible placed in an oven and heated to 450 ° C under an argon atmosphere for 2 hours. The strips of fabric were cooled to room temperature and stored in the dark under an argon atmosphere. The activated strips of fabric incorporated an additional 0.20% by weight of Pt as a result of the chemical treatment. Several pieces of strips of activated catalyst ignition promoter were brought into contact with a platinum catalyst screen used in the manufacture of cyanohydrin acetone. The ignition of the converter was successful on the first attempt. The ignition occurred with feed rates between 7.0 and 11.5 air / NH3 and between 0.70 - 1.2 CH4 / NH3 as the pressure was increased between 0 kPa man to 248 kPa man. The ignition temperature was 234 ° C and increased to 360 ° C (at 193 kPa man) as measured using a multiplexor temperature recording unit. Thermocouples were placed under each ignition strip and it appeared that ignition events occurred on each strip before complete ignition of the screen occurred within 1 hour, based on readings from the thermocouples. The low ignition temperature indicates that the activated strips were unexpectedly effective in promoting complete ignition of the catalytic screen. The ignition data is summarized in Table 1. Table 1. Data for Pt screens promoted for ignition.

The catalyst ignition promoter strips were also effective for igniting damaged and contaminated screens, significantly reducing the costs associated with misfire. In all attempts the ignition of the catalyst was successful on the first attempt, with the use of the activated ignition promoter strips of the invention.

It should be understood that the embodiments of the present invention described above are merely examples and that a person skilled in the art can produce variations and modifications without deviating from the spirit and scope of the invention. All such variations and modifications are intended to be included within the scope of the present invention.

Claims (2)

1. Process for preparing one or more catalyst ignition promoters, characterized by the fact that it comprises the step of treating one or more sections of a screen catalyst selected from the group consisting of: a used catalyst, a contaminated catalyst, a damaged catalyst and combinations thereof and comprising one or more metals selected from the group consisting of nickel, platinum, palladium, cobalt, rhodium, silver, gold, copper, iridium, rhenium, cerium, alloys thereof, binary alloys thereof, ternary alloys thereof, intermetallics thereof and combinations thereof, with one or more chemical treatments or a combination of one or more chemical and physical treatments; where each section of the catalyst is coated with a metal coating comprising between 0.01 and 1 weight percent of a metal coating, based on the weight of the catalyst, of one or more metals selected from the group consisting of nickel, platinum, palladium, cobalt, rhodium, silver, gold, copper, iridium, rhenium, cerium, alloys thereof, binary alloys thereof, ternary alloys thereof, intermetallic alloys thereof and combinations thereof. Process according to claim 1, characterized in that the metal coating is prepared from one or more metal compounds selected from the group consisting of: platinum black, Raney Ni, metal halides (F, Cl , Br, I and combinations thereof), metal ammonia complexes, organometallic compounds, metal carbonyls and metal olefins, metal hydrides and combinations thereof.